JP2010062949A - Receiver and signal transmission system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a receiver and signal transmission system, capable of canceling screen shaking and flickering or the like. <P>SOLUTION: A receiving apparatus 20 can be connected to a transmission apparatus 10 that transmits RGB image signals, a vertical synchronizing signal and a horizontal synchronizing signal and transmits and receives differential signals on a pair of signal lines, and includes: an adjustment circuit 233 which adjusts a potential at a midpoint on a side of the receiving apparatus 20 between the pair of signal lines such that the potential at the midpoint on the side of the receiving apparatus becomes equal to a potential at a midpoint on a side of the transmission apparatus 10 between the pair of signal lines; a control circuit 232 which controls rising and falling speeds of the differential signals flowing on the pair of signal lines; and a cancel circuit 25 which cancels a crosstalk, that is incurred in the horizontal synchronizing signal by the vertical synchronizing signal, by input of the vertical synchronizing signal. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a receiver and a signal transmission system capable of transmitting an image signal at a long distance (for example, several hundred meters).

Conventionally, a local unit that sends analog image signals (ie RGB signals) output from a computer and response signals for keyboard and mouse operations to a remote location via a Cat5 (category 5) cable, etc., and keyboard and mouse operation signals And a remote unit that receives the analog image signal and the response signal are known.
JP 2004-356939 A

  However, in the signal transmission system, complete balanced transmission cannot be performed with the signal lines of the keyboard and mouse operation signals and response signals, and EMI noise occurs. This EMI noise affects the analog image signal as so-called crosstalk, causing the screen of a remote monitor to shake or flicker.

  An object of the present invention is to provide a receiver and a signal transmission system that can eliminate screen shaking and flickering.

  In order to achieve the above object, the receiver of the present invention is a receiver that can be connected to a transmitter that transmits a plurality of image signals, a vertical synchronization signal, and a horizontal synchronization signal and transmits and receives a differential signal on a pair of signal lines. And the potential at the midpoint of the receiver side between the pair of signal lines is the same as the potential at the midpoint of the transmitter side between the pair of signal lines. An adjustment circuit for adjusting the vertical synchronization signal, a control circuit for controlling the rising and falling speeds of the differential signals flowing on the pair of signal lines, and crosstalk caused by the vertical synchronization signal generated in the horizontal synchronization signal to the vertical synchronization signal. And a cancel circuit for canceling by inputting.

  According to this configuration, the adjustment circuit and the control circuit suppress the generation of EMI noise that affects the communication of the image signal, and the cancel circuit cancels the crosstalk caused by the vertical synchronization signal generated in the horizontal synchronization signal due to the remaining EMI noise. Therefore, it is possible to eliminate the shaking and flickering of the image in the screen.

  The receiver according to claim 2 is the receiver according to claim 1, wherein a first synchronization signal separation circuit separates a horizontal synchronization signal multiplexed into one of the plurality of image signals from the at least one image signal. And a second synchronization signal separation circuit that separates the vertical synchronization signal multiplexed on the other one of the plurality of image signals from the image signal, and the vertical synchronization signal includes the horizontal synchronization signal and the potential. The cancel circuit is composed of two resistors connected in series between two input terminals of the first synchronization signal separation circuit, and the output terminal of the second synchronization signal separation circuit is It is characterized by being connected via a signal line between two resistors.

  According to such a configuration, the vertical synchronization signal separated by the second synchronization signal separation circuit is input between the two resistors, and crosstalk due to the vertical synchronization signal generated in the horizontal synchronization signal can be canceled.

  The receiver according to claim 3 is the receiver according to claim 2, further comprising a plurality of detection circuits for detecting the plurality of image signals, the plurality of detection circuits, the first synchronization signal separation circuit, and the second A plurality of diodes are provided on a plurality of signal lines connecting the synchronization signal separation circuits.

  According to such a configuration, it is possible to remove impulse noise multiplexed on the image signal from the external environment.

  The receiver according to claim 4 is the receiver according to claim 1, wherein two horizontal synchronizing signals multiplexed into two of the plurality of image signals respectively flow as differential signals. A line group and a third signal line group in which a vertical synchronizing signal multiplexed on the other one of the plurality of image signals flows as a differential signal, and the vertical synchronizing signal includes the horizontal synchronizing signal and a potential The cancel circuit includes a midpoint of a first termination resistor provided between the first signal line groups and a midpoint of a second termination resistor provided between the second signal line groups. A plurality of resistors connected to each other, and one of the plurality of resistors includes a middle point of a third termination resistor provided between the third signal line groups so that a resistance value can be adjusted. It is connected.

  According to such a configuration, the cancel circuit aligns the level of the common mode signal of the horizontal synchronization signal multiplexed into two of the plurality of image signals, and at the same time, crosstalk of the vertical synchronization signal mixed in the horizontal synchronization signal is performed. Can be countered. Therefore, it is possible to eliminate the shaking and flickering of the image on the screen.

  The receiver according to claim 5 is the receiver according to claim 4, provided between the second signal line group and the potential of the middle point of the first termination resistor provided between the first signal line groups. Detecting means for detecting a potential difference at the middle point of the second termination resistor and a resistance value of the resistor connected to the middle point of the third termination resistor so that the potential difference detected by the detection means becomes zero. And an adjusting means for automatically adjusting.

  According to such a configuration, the level of the common mode signal of the horizontal synchronization signal multiplexed into two of the plurality of image signals is automatically aligned, and at the same time, the crosstalk of the vertical synchronization signal mixed in the horizontal synchronization signal is automatically performed. Can be counteracted.

  The receiver according to claim 6 is the receiver according to claim 4 or 5, wherein a diode is connected to a middle point of the first termination resistor, the second termination resistor, and the third termination resistor. It is characterized by that.

  According to such a configuration, it is possible to remove impulse noise multiplexed on the image signal from the external environment.

  8. The signal transmission system according to claim 7, wherein the transmitter transmits a plurality of image signals, a vertical synchronization signal, and a horizontal synchronization signal, and transmits and receives a differential signal on a pair of signal lines, and the plurality of image signals and the vertical synchronization signal. And a receiver that receives the horizontal synchronization signal and transmits and receives differential signals on a pair of signal lines, wherein the transmitter is a midpoint on the receiver side between the pair of signal lines. And a first adjustment circuit that adjusts the potential at the midpoint of the transmitter side between the pair of signal lines and the pair of signal lines so that the potential of A first control circuit that controls a rising speed and a falling speed of the differential signal, and the receiver transmits a potential between the pair of signal lines between the pair of signal lines. To be the same as the midpoint potential on the aircraft side, A second adjustment circuit that adjusts the potential at the midpoint of the receiver side, a second control circuit that controls the rising and falling speeds of the differential signals flowing on the pair of signal lines, and the horizontal synchronizing signal And a cancel circuit that cancels crosstalk caused by the vertical synchronization signal by inputting the vertical synchronization signal.

  According to this configuration, the adjustment circuit and the control circuit suppress the generation of EMI noise that affects the communication of the image signal, and the cancel circuit cancels the crosstalk caused by the vertical synchronization signal generated in the horizontal synchronization signal due to the remaining EMI noise. Therefore, it is possible to eliminate the shaking and flickering of the image in the screen.

  The signal transmission system according to claim 8 is the signal transmission system according to claim 7, wherein the receiver separates a horizontal synchronization signal multiplexed into one of the plurality of image signals from the at least one image signal. And a second synchronization signal separation circuit for separating a vertical synchronization signal multiplexed on the other one of the plurality of image signals from the image signal, wherein the vertical synchronization signal is The polarity of the potential is different from that of the horizontal synchronizing signal, and the cancel circuit is composed of two resistors connected in series between two input terminals of the first synchronizing signal separation circuit, and the second synchronizing signal The output terminal of the separation circuit is connected between the two resistors via a signal line.

  According to such a configuration, the vertical synchronization signal separated by the second synchronization signal separation circuit is input between the two resistors, and crosstalk due to the vertical synchronization signal generated in the horizontal synchronization signal can be canceled.

  The signal transmission system according to claim 9 is the signal transmission system according to claim 8, wherein the receiver includes a plurality of detection circuits that detect the plurality of image signals, and the plurality of detection circuits and the first synchronization. A plurality of diodes are provided on a plurality of signal lines connecting the signal separation circuit and the second synchronization signal separation circuit.

  According to such a configuration, it is possible to remove impulse noise multiplexed on the image signal from the external environment.

  The signal transmission system according to claim 10 is the signal transmission system according to claim 7, wherein in the receiver, two horizontal synchronization signals multiplexed into two of the plurality of image signals flow as differential signals, respectively. A first signal line group and a third signal line group in which a vertical synchronizing signal multiplexed on the other one of the plurality of image signals flows as a differential signal; The polarity of the potential is different from that of the horizontal synchronization signal, and the cancel circuit is provided between a middle point of a first termination resistor provided between the first signal line groups and a second signal line group. A plurality of resistors that connect between the middle points of the two terminal resistors, and one of the plurality of resistors is provided between the third signal line groups so that the resistance value can be adjusted. 3 It is connected to the middle point of the terminating resistor.

  According to such a configuration, the cancel circuit aligns the level of the common mode signal of the horizontal synchronization signal multiplexed into two of the plurality of image signals, and at the same time, crosstalk of the vertical synchronization signal mixed in the horizontal synchronization signal is performed. Can be countered. Therefore, it is possible to eliminate the shaking and flickering of the image on the screen.

  The signal transmission system according to claim 11 is the signal transmission system according to claim 10, wherein the receiver has a potential at a midpoint of a first termination resistor provided between the first signal line groups and the second signal. Detecting means for detecting a potential difference at the middle point of the second termination resistor provided between the signal line groups of the first and second signal lines, and connecting to the middle point of the third termination resistor so that the potential difference detected by the detection means becomes zero. And adjusting means for automatically adjusting the resistance value of the resistor.

  According to such a configuration, the level of the common mode signal of the horizontal synchronization signal multiplexed into two of the plurality of image signals is automatically aligned, and at the same time, the crosstalk of the vertical synchronization signal mixed in the horizontal synchronization signal is automatically performed. Can be counteracted.

  A signal transmission system according to a twelfth aspect is the signal transmission system according to the tenth or eleventh aspect, wherein a diode is connected to each middle point of the first termination resistor, the second termination resistor, and the third termination resistor. It is characterized by.

  According to such a configuration, it is possible to remove impulse noise multiplexed on the image signal from the external environment.

  According to the present invention, it is possible to eliminate shaking and flickering of an image in a screen.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a block diagram showing a configuration of a signal transmission system according to an embodiment of the present invention.

  As shown in FIG. 1, in the signal transmission system, a transmission device 10 and a reception device 20 are provided between a server 30, a display 40, and a keyboard or mouse (hereinafter referred to as a keyboard / mouse) 50.

  The transmission device 10 and the reception device 20 are connected to each other via the LAN cable 100. The transmitting device 10 and the receiving device 20 incorporate dedicated interfaces (hereinafter, the interface is abbreviated as I / F) 10A and 20A, respectively. The dedicated I / F 10A and the dedicated I / F 20A connect the transmission device 10 and the reception device 20 in a one-to-one relationship. The dedicated I / F 10A includes three image signals (RGB: hereinafter, simply referred to as an image signal if any), a horizontal synchronization signal (Hsync), and a vertical synchronization signal (Vsync) (hereinafter, any case may be used). A simple synchronization signal) is transmitted to the dedicated I / F 20A, and a signal input from the keyboard / mouse 50 (referred to as an operation signal) is received from the dedicated I / F 20A. The dedicated I / F 20A receives an image signal and a synchronization signal from the dedicated I / F 10A and transmits an operation signal to the dedicated I / F 10A.

  The LAN cable 100 is a Cat5E straight cable, for example, and includes four pairs (a total of eight) of signal lines. Each image signal is transmitted as a differential signal from the transmission device 10 to the reception device 20, and thus occupies a pair of signal lines for each image signal. Therefore, three image signals, that is, RGB signals occupy three pairs of signal lines. The remaining pair of signal lines are used to transmit an operation signal input from the keyboard / mouse 50 from the reception device 20 to the transmission device 10 and also output a signal output from the server 30 from the transmission device 10 to the reception device. Used to send to 20. As will be described later, since the horizontal synchronization signal is multiplexed with the G signal and the vertical synchronization signal is multiplexed with the B signal, the horizontal synchronization signal and the vertical synchronization signal each occupy the signal line independently. Absent.

  The transmission apparatus 10 includes a VGA (Video Graphics Array) connector 10B as a display connector for inputting an image signal (RGB), a horizontal synchronization signal, and a vertical synchronization signal from a server 30 configured by a personal computer or a workstation. . For the VGA connector 10B, a general connector such as a BNC connector or a D-sub15 pin connector can be used.

  The transmission device 10 also includes a connector 10 </ b> C for inputting an operation signal of the keyboard / mouse 50 input via the reception device 20 to the server 30.

  The server 30 is provided with a VGA connector 30A for outputting image signals (RGB) and a connector 30B for inputting operation signals from a keyboard or a mouse, as in a general information processing apparatus. Yes. Therefore, the VGA connector 10B provided in the transmission device 10 is connected to the VGA connector 30A provided in the server 30 via the RGB cable 200A configured using, for example, a BNC cable, a D-sub15pin cable, or the like. The connector 10C provided in the transmission device 10 is connected to a connector 30B provided in the server 30 via a cable 300A used for connecting a general keyboard and mouse. The connector 10C and the connector 30B are configured with USB (Universal Serial Bus) or PS / 2 connectors, and the cable 300A is configured with a USB (Universal Serial Bus) or PS / 2 cable. .

  The receiving apparatus 20 includes a VGA (Video Graphics Array) connector 20B as a display connector for outputting an image signal (RGB), a horizontal synchronization signal, and a vertical synchronization signal to the display 40. For the VGA connector 20B, a general connector such as a BNC connector or a D-sub15 pin connector can be used. An RGB cable 200B provided on the display 40 is connected to the VGA connector 20B. The RGB cable 200B is configured by, for example, a BNC cable, a D-sub15 pin cable, or the like.

  Further, the receiving device 20 includes a connector 20 </ b> C for inputting an operation signal from the keyboard / mouse 50. A cable 300B provided on the keyboard / mouse 50 is connected to the connector 20C. The connector 20C is configured with a USB (Universal Serial Bus) or PS / 2 connector, and the cable 300B is configured with a USB (Universal Serial Bus) or PS / 2 cable.

  Next, the internal configurations of the transmission device 10 and the reception device 20 will be described in detail with reference to the drawings. In the following description, the case where the horizontal synchronizing signal is multiplexed with the image signal (G) and the vertical synchronizing signal is multiplexed with the image signal (B) among the R, G, B image signals will be described as an example. To do.

  FIG. 2 is a block diagram illustrating an internal configuration of the transmission apparatus 10. As shown in FIG. 2, the transmission device 10 multiplexes the horizontal synchronization signal with the image signal (G) among the image signals (RGB) input from the VGA connector 10 </ b> B, and converts the vertical synchronization signal into the image signal (B). Multiplexing circuits 11a and 11b for multiplexing and a serial communication driver 12 are provided.

  The multiplexing circuit 11 a receives the image signal (G) and the horizontal synchronization signal among the image signals (RGB), multiplexes the horizontal synchronization signal with the image signal (G), and outputs the multiplexed signal to the receiving device 20. Similarly, the multiplexing circuit 11b receives the image signal (B) and the vertical synchronizing signal among the image signals (RGB), multiplexes the vertical synchronizing signal with the image signal (B), and sends the multiplexed signal to the receiving device 20. Output. Note that the voltage level of a general image signal (RGB) is at most about 1V, and the voltage level of a general synchronization signal is about 5V, which is equivalent to the internal voltage level. The serial communication driver 12 includes an RS-485 serial communication driver, and outputs an operation signal received from the receiving device 20 to the server 30 and transmits a signal from the server 30 to the receiving device 20.

  FIG. 3 is a block diagram illustrating an internal configuration of the receiving device 20.

  The receiving device 20 includes image signal detection circuits 21a to 21c (detection circuits), synchronization signal separation circuits 22a and 22b, and a serial communication driver 23. The synchronization signal separation circuit 22a corresponds to a first synchronization signal separation circuit, and the synchronization signal separation circuit 22b corresponds to a second synchronization signal separation circuit.

  The image signal detection circuits 21a to 21c detect the image signal (R), the image signal (G), and the image signal (B) from the plurality of signals received by the dedicated I / F 20A. The synchronization signal separation circuit 22b separates the vertical synchronization signal from the common mode signal output from the image signal detection circuit 21c based on the common mode signal output from the image signal detection circuit 21a. The synchronization signal separation circuit 22a removes the influence of crosstalk due to the vertical synchronization signal from the common mode signal output from the image signal detection circuit 21b based on the common mode signal and the vertical synchronization signal output from the image signal detection circuit 21a. Separate horizontal sync signals.

  The serial communication driver 23 is configured by an RS-485 serial communication driver, and outputs an operation signal received from the mouse / driver 50 to the transmission device 10 and transmits a signal from the transmission device 10 to a USB device (not shown). Send to.

  FIG. 4 is a diagram illustrating a connection state between the serial communication driver 12 and the serial communication driver 23.

  The serial communication driver 12 and the serial communication driver 23 perform bidirectional communication via a pair of signal lines 61 and 62. However, since this communication is not complete balanced transmission, EMI noise is generated. This EMI noise affects the horizontal synchronization signal as so-called crosstalk, causing the screen of the display 40 at a remote location to shake or flicker.

  In the present embodiment, the potentials at the midpoints A and B between a pair of signal lines are adjusted to about 2.5 V, and the bidirectional communication performed between the serial communication driver 12 and the serial communication driver 23 is balanced. Make transmission. A signal that is bidirectionally communicated between the serial communication driver 12 and the serial communication driver 23 is 1 V peak-to-peak, and the reference voltage (amplitude center voltage) of the signal is about 2.5 V (power supply voltage Vcc). By setting the voltage value to about half of the voltage value, AC balanced transmission is performed.

  As shown in FIG. 4, between the serial communication driver 12 and the serial communication driver 23, the rising and falling edges of the signal pulses flowing on the termination resistors 121 and 231 and the signal lines 61 and 62 become gentle. As described above, the control circuits 122 and 232 for controlling the rising and falling speeds of the signal pulse and the adjustment circuit for adjusting the operating point (ie, the reference voltage) of the signal pulse flowing on the signal lines 61 and 62 to about 2.5V. 123 and 233 are provided.

  The adjustment circuits 123 and 233 adjust the potential at the midpoint between the pair of signal lines to an appropriate value (that is, about 2.5 V), thereby reducing EMI noise. Further, since the control circuits 122 and 232 appropriately slow down the rising and falling speeds of the signal pulses flowing on the signal lines 61 and 62, harmonics are emitted from the serial communication driver 12 and the serial communication driver 23. EMI noise is reduced.

  FIG. 5 is a diagram showing a detailed hardware configuration of the receiving device 20 excluding the serial communication driver 23.

  As shown in FIG. 5, termination resistor circuits 24a to 24c are provided on the input sides of the image signal detection circuits 21a to 21c, respectively. Each of the terminal resistance circuits 24a to 24c is connected between three pairs of signal lines 27a to 27c, and includes two 50Ω resistors. The midpoint of the two 50Ω resistors is grounded. The image signal detection circuits 21a to 21c respectively output an R signal, a G signal, and a B signal and a common mode signal.

  A cancel circuit 25 for canceling crosstalk due to the vertical sync signal is provided on the input side of the sync signal separation circuit 22a. The cancel circuit 25 includes a resistor Ra and a resistor Rb, and a point P between the resistor Ra and the resistor Rb is connected to the output side of the synchronization signal separation circuit 22b. The ratio of the resistance values of the resistor Ra and the resistor Rb is preferably 1: 3.

  As described above, the EMI noise generated by the bidirectional communication between the serial communication driver 12 and the serial communication driver 23 is reduced by the control circuits 122 and 232 and the adjustment circuits 123 and 233, but the remaining EMI noise. Causes the horizontal synchronization signal and the vertical synchronization signal to fluctuate as crosstalk.

  Here, an enlarged example of the output waveform of the horizontal synchronizing signal is shown in FIG. 6A, an enlarged example of the output waveform of the vertical synchronizing signal is shown in FIG. 6B, and a reduced example of the output waveform of the horizontal synchronizing signal is shown. 6 (C). 6A and 6B, when the polarity of the horizontal synchronization signal is positive, the polarity of the vertical synchronization signal is negative. That is, the horizontal synchronization signal is the same as the vertical synchronization signal. It is an output waveform of a reverse potential.

  In FIG. 6C, due to EMI noise, the output waveform of the horizontal synchronization signal is raised by 140 mV from the normal state when the vertical synchronization signal is output. As a result, image shaking and flickering occur on the screen of the display 40.

  Therefore, in this embodiment, the output point M of the synchronization signal separation circuit 22b is connected to the point P between the resistors Ra and Rb, and the vertical synchronization signal having the opposite polarity to the horizontal synchronization signal is input to the cancel circuit 25. By doing so, the crosstalk caused by the vertical synchronization signal that affects the output of the horizontal synchronization signal is canceled. FIG. 6D shows a reduction example of the output waveform of the horizontal synchronization signal after the crosstalk due to the vertical synchronization signal is canceled.

  Three pairs of signal lines 27a to 27c for inputting image signals are included in the LAN cable 100 of FIG. The image signals flowing through the three pairs of signal lines 27a to 27c may include an impulse that is noise depending on the external environment. This impulse adversely affects the vertical synchronization signal and the horizontal synchronization signal, and causes a blackout in which the image displayed on the display 40 becomes one black color.

  In order to avoid this blackout, as shown in FIG. 5, Zener diodes 26a to 26c are provided in the output path of the common mode signal of the image signal detection circuits 21a to 21c. The zener diodes 26a to 26c remove noise (that is, impulse) added to the common mode signal output from the image signal detection circuits 21a to 21c.

  FIG. 7 is a diagram illustrating a first modification of the detailed hardware configuration of the receiving device 20 excluding the serial communication driver 23.

  In this case, it is assumed that the horizontal synchronizing signal is multiplexed with the image signal (R) and the image signal (B), and the vertical synchronizing signal is multiplexed with the image signal (G).

  As illustrated in FIG. 7, the reception device 20 includes an image signal detection & synchronization signal separation circuit 307. The image signal detection & synchronization signal separation circuit 307 incorporates the image signal detection circuits 21a to 21c and the synchronization signal separation circuits 22a and 22b of FIG. 3 in one chip. Therefore, the image signal detection & synchronization signal separation circuit 307 has the same function as the image signal detection circuits 21a to 21c and the synchronization signal separation circuits 22a and 22b in FIG. Furthermore, the image signal detection & synchronization signal separation circuit 307 has an image signal and synchronization signal gain and an equalizer automatic correction function.

  Further, three pairs of signal lines (301a, 301b, 302a, 302b, 303a, 303b) are connected to the input side of the image signal detection & synchronization signal separation circuit 307, and the signal lines 301a and 301b are connected to each other. A termination resistor 304 is provided between them. A termination resistor 305 is provided between the signal line 302a and the signal line 302b, and a termination resistor 306 is provided between the signal line 303a and the signal line 303b. The signal lines 301a and 301b correspond to the first signal line group, the signal lines 303a and 303b correspond to the second signal ship group, and the signal lines 302a and 302b correspond to the third signal line group.

  One end of the resistor Rr and the capacitor 308 is connected to the point R1 between the signal line 301a and the signal line 301b, and the other end of the resistor Rr and the capacitor 308 is grounded. A Zener diode 312 for removing noise (impulse added to the image signal (R) from the outside) is connected between the resistor Rr and one end of the capacitor 308 and the point R1.

  A point G1 between the signal line 302a and the signal line 302b is grounded via a resistor Rg. A Zener diode 313 for removing noise (impulse added to the image signal (G) from the outside) is connected between the point G1 and the resistor Rg. Further, a power supply of 3.3 V is connected between the point G1 and the resistor Rg via a noise removing capacitor 315.

  One end of the resistor Rb and the capacitor 309 is connected to the point B1 between the signal line 303a and the signal line 303b, and the other end of the resistor Rb and the capacitor 309 is grounded. A Zener diode 313 for removing noise (impulse added to the image signal (B) from the outside) is connected between the resistor Rb and one end of the capacitor 309 and the point B1.

  Although it is possible to provide Zener diodes for noise removal on all three pairs of signal lines, if the voltage at the operating point of each image signal varies, the effect on noise is reduced by half. The zener diode for use is connected to the midpoint of each pair of signal lines.

  The point R1 is connected to the point B1 through the resistor 310, the resistor Rrb, and the resistor 311. The point G1 is connected to the resistor Rrb so that the potentials at the points R1 and G1 can be adjusted.

  The resistor Rrb constitutes an image quality adjustment volume switch 320. The user operates the image quality adjustment switch 320 to balance the potentials of the common mode signals of the horizontal synchronization signals at the points R1 and G1. For example, the point where the potentials of the common mode signals of the horizontal synchronization signals at the points R1 and G1 are balanced is a position where no flicker occurs at the top of the screen when a gray screen is displayed on the display 40. At this time, since the vertical synchronizing signal (that is, the waveform of the reverse potential of the horizontal synchronizing signal) multiplexed on the image signal (G) is input from the point G1 to the resistor Rrb, the image signal (R) and the image signal ( Crosstalk due to the vertical synchronizing signal mixed in the horizontal synchronizing signal of B) is canceled.

  As described above, the receiving device 20 in FIG. 7 aligns the level of the common mode signal of the horizontal synchronization signal multiplexed in the image signal (R) and the image signal (B), and is simultaneously mixed in the horizontal synchronization signal. Since the image quality adjustment volume switch 320 for canceling the crosstalk of the vertical synchronizing signal is provided, it is possible to eliminate the shaking and flickering of the image generated on the display 40.

  FIG. 8 is a diagram illustrating a second modification example of the detailed hardware configuration of the receiving device 20 excluding the serial communication driver 23.

  In the configuration of FIG. 8, a comparator 321, an AD converter 322, an A / D conversion circuit 323, an MPU 324, and an automatic adjustment button 325 are added to the configuration of FIG. These components correspond to adjustment means. Here, the image quality adjustment volume switch 320 is composed of an electronic switch that automatically adjusts the values on the R side and B side of the resistor Rrb based on a control signal from the MPU 324.

  The comparator 321 is mixed with the horizontal synchronization signal at the point G1 where the crosstalk due to the vertical synchronization signal is mixed, the potential of the common mode signal of the horizontal synchronization signal at the point R1 and the crosstalk due to the vertical synchronization signal is mixed. The difference in the potential of the common mode signal is detected. The AD converter 322 A / D converts the output from the comparator 321. The A / D conversion circuit 323 is mixed with crosstalk due to the vertical synchronization signal, mixed with the potential of the common mode signal of the horizontal synchronization signal at the point R1 and crosstalk due to the vertical synchronization signal. The potential of the common mode signal of the horizontal synchronization signal is A / D converted.

  When the automatic adjustment button 325 is pressed, the MPU 324 is mixed with crosstalk due to the vertical synchronization signal, mixed with the potential of the common mode signal of the horizontal synchronization signal at the point R1 and crosstalk due to the vertical synchronization signal. A control signal is output to the image quality adjustment volume switch 320 such that the difference in potential of the common mode signal of the horizontal synchronization signal at the point G1 becomes zero.

  For example, as shown in FIG. 9, the potential of the common mode signal of the horizontal synchronization signal at the point R1, where crosstalk due to the vertical synchronization signal is mixed, is 380 mV lower than the reference potential, and crossing due to the vertical synchronization signal It is assumed that the potential of the common mode signal of the horizontal synchronization signal at the point B1 where the talk is mixed is 394 mv lower than the reference potential. In this case, since the difference between the two potentials is 14 mV, the MPU 324 outputs a control signal to the image quality adjustment volume switch 320 such that both potentials are 387 mV lower than the reference potential.

  The image quality adjustment volume switch 320 adjusts the values on the R side and B side of the resistor Rrb based on this control signal. At this time, since the vertical synchronizing signal (that is, the waveform of the reverse potential of the horizontal synchronizing signal) multiplexed on the image signal (G) is input from the point G1 to the resistor Rrb, the image signal (R) and the image signal ( Crosstalk due to the vertical synchronizing signal mixed in the horizontal synchronizing signal of B) is canceled.

  As described above, the receiving device 20 of FIG. 8 also aligns the level of the common mode signal of the horizontal synchronization signal multiplexed in the image signal (R) and the image signal (B), and is simultaneously mixed in the horizontal synchronization signal. Since the crosstalk of the vertical synchronization signal is canceled, the shaking and flickering of the image generated on the display 40 can be eliminated, and a very clear image can be displayed.

  7 and 8, the receiving device 20 does not show the serial communication driver 23, but includes the serial communication driver 23 and a circuit group shown in FIG.

  As described above, according to the present embodiment, the reception device 20 transmits the RGB image signal, the vertical synchronization signal, and the horizontal synchronization signal, and transmits and receives the differential signal on the pair of signal lines. Connectable, and the receiving device 20 side midpoint potential between the pair of signal lines is the same as the midpoint potential of the transmitting device 10 side between the pair of signal lines. An adjustment circuit 233 for adjusting the potential at the midpoint, a control circuit 232 for controlling the rising and falling speeds of the differential signals flowing on the pair of signal lines, and vertical crosstalk caused by the vertical synchronization signal generated in the horizontal synchronization signal And a cancel circuit 25 that cancels by inputting a synchronization signal.

  Therefore, the adjustment circuit 233 and the control circuit 232 suppress the generation of EMI noise that affects the image signal communication, and the cancel circuit 25 cancels the crosstalk caused by the vertical synchronization signal generated in the horizontal synchronization signal due to the remaining EMI noise. It is possible to eliminate shaking and flickering of the image in the screen. As a result, the display 40 can display a very clear image.

In the above embodiment, the Zener diodes 26a to 26c or the Zener diode 313 are used as the diode for noise removal, but a Schottky diode for noise removal may be used.

  The present invention is not limited to the above-described embodiment, and can be implemented with various modifications within a range not departing from the gist thereof.

It is a block diagram which shows the structure of the signal transmission system which concerns on embodiment of this invention. 2 is a block diagram showing an internal configuration of a transmission device 10. FIG. 3 is a block diagram showing an internal configuration of a receiving device 20. FIG. 4 is a diagram illustrating a connection state between a serial communication driver 12 and a serial communication driver 23. FIG. 3 is a diagram illustrating a detailed hardware configuration of a receiving device 20 excluding a serial communication driver 23. FIG. (A) is a figure which shows the example of expansion of the output waveform of a horizontal synchronizing signal, (B) is a figure which shows the example of expansion of the output waveform of a vertical synchronizing signal, (C) is reduction of the output waveform of a horizontal synchronizing signal. It is a figure which shows an example, (D) is a figure which shows the reduction example of the output waveform of a horizontal synchronizing signal after the crosstalk by a vertical synchronizing signal is canceled. FIG. 12 is a diagram illustrating a first modification of a detailed hardware configuration of the receiving device 20 excluding the serial communication driver 23. FIG. 11 is a diagram illustrating a second modification of the detailed hardware configuration of the receiving device 20 excluding the serial communication driver 23. It is a figure which shows the waveform of the point R1, the point G1, and the point B1 where the crosstalk by a vertical synchronizing signal is mixed.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Transmission apparatus 12,23 Serial communication driver 25 Cancel circuit 20 Reception apparatus 30 Server 40 Display 50 Keyboard / mouse 100 LAN cable 121,231 Termination resistor 122,232 Control circuit 123,233 Adjustment circuit

Claims (12)

A receiver that can be connected to a transmitter that transmits a plurality of image signals, a vertical synchronization signal, and a horizontal synchronization signal and transmits and receives a differential signal on a pair of signal lines,
Adjust the midpoint potential of the receiver side between the pair of signal lines so that the midpoint potential of the receiver side between the pair of signal lines is the same as the midpoint potential of the transmitter side between the pair of signal lines. An adjustment circuit;
A control circuit for controlling the rising and falling speeds of the differential signals flowing on the pair of signal lines;
A receiver comprising: a cancel circuit that cancels crosstalk caused by the vertical synchronization signal generated in the horizontal synchronization signal by inputting the vertical synchronization signal. A first synchronization signal separation circuit for separating a horizontal synchronization signal multiplexed into one of the plurality of image signals from the at least one image signal;
A second synchronization signal separation circuit for separating a vertical synchronization signal multiplexed on the other one of the plurality of image signals from the image signal;
The vertical synchronization signal is different in potential polarity from the horizontal synchronization signal,
The cancel circuit includes two resistors connected in series between two input terminals of the first synchronization signal separation circuit, and an output terminal of the second synchronization signal separation circuit is between the two resistors. The receiver according to claim 1, wherein the receiver is connected to the receiver via a signal line.   A plurality of detection circuits for detecting the plurality of image signals, wherein a plurality of diodes are provided on a plurality of signal lines connecting the plurality of detection circuits to the first synchronization signal separation circuit and the second synchronization signal separation circuit; The receiver according to claim 2. A first signal line group and a second signal line group in which two horizontal synchronization signals multiplexed into two of the plurality of image signals respectively flow as differential signals;
A third signal line group in which a vertical synchronizing signal multiplexed on another one of the plurality of image signals flows as a differential signal;
The vertical synchronization signal is different in potential polarity from the horizontal synchronization signal,
The cancel circuit connects between a midpoint of a first termination resistor provided between the first signal line groups and a midpoint of a second termination resistor provided between the second signal line groups. A plurality of resistors are provided, and one of the plurality of resistors is connected to a midpoint of a third termination resistor provided between the third signal line groups so that the resistance value can be adjusted. The receiver according to claim 1.   Detecting means for detecting a potential difference between a midpoint of a first termination resistor provided between the first signal line groups and a midpoint of a second termination resistor provided between the second signal line groups; 5. An adjusting means for automatically adjusting a resistance value of a resistor connected to a middle point of the third terminal resistor so that a potential difference detected by the detecting means becomes zero. As described in the receiver.   6. The receiver according to claim 4, wherein a diode is connected to each of midpoints of the first termination resistor, the second termination resistor, and the third termination resistor. A transmitter for transmitting a plurality of image signals, a vertical synchronization signal, and a horizontal synchronization signal and transmitting / receiving a differential signal on a pair of signal lines; and receiving the plurality of image signals, the vertical synchronization signal, and the horizontal synchronization signal A signal transmission system having a receiver for transmitting and receiving differential signals on a pair of signal lines,
The transmitter is
Adjust the midpoint potential of the transmitter side so that the midpoint potential of the receiver side between the pair of signal lines is the same as the midpoint potential of the transmitter side between the pair of signal lines. A first adjustment circuit;
A first control circuit for controlling the rising and falling speeds of the differential signals flowing on the pair of signal lines,
The receiver
Adjust the midpoint potential of the receiver side between the pair of signal lines so that the midpoint potential of the receiver side between the pair of signal lines is the same as the midpoint potential of the transmitter side between the pair of signal lines. A second adjustment circuit;
A second control circuit for controlling the rising and falling speeds of the differential signals flowing on the pair of signal lines;
A signal transmission system comprising: a cancel circuit that cancels crosstalk caused by the vertical synchronization signal generated in the horizontal synchronization signal by inputting the vertical synchronization signal. The receiver
A first synchronization signal separation circuit for separating a horizontal synchronization signal multiplexed into one of the plurality of image signals from the at least one image signal;
A second synchronization signal separation circuit for separating a vertical synchronization signal multiplexed on the other one of the plurality of image signals from the image signal;
The vertical synchronization signal is different in potential polarity from the horizontal synchronization signal,
The cancel circuit includes two resistors connected in series between two input terminals of the first synchronization signal separation circuit, and an output terminal of the second synchronization signal separation circuit is between the two resistors. The signal transmission system according to claim 7, wherein the signal transmission system is connected to the signal line via a signal line.   The receiver includes a plurality of detection circuits that detect the plurality of image signals, and a plurality of signal lines that connect the plurality of detection circuits to the first synchronization signal separation circuit and the second synchronization signal separation circuit. The signal transmission system according to claim 8, wherein a diode is provided. The receiver
A first signal line group and a second signal line group in which two horizontal synchronization signals multiplexed into two of the plurality of image signals respectively flow as differential signals;
A third signal line group in which a vertical synchronizing signal multiplexed on another one of the plurality of image signals flows as a differential signal;
The vertical synchronization signal is different in potential polarity from the horizontal synchronization signal,
The cancel circuit connects between a midpoint of a first termination resistor provided between the first signal line groups and a midpoint of a second termination resistor provided between the second signal line groups. A plurality of resistors are provided, and one of the plurality of resistors is connected to a midpoint of a third termination resistor provided between the third signal line groups so that the resistance value can be adjusted. The signal transmission system according to claim 7.   The receiver detects a potential difference between a midpoint of a first termination resistor provided between the first signal line groups and a midpoint of a second termination resistor provided between the second signal line groups. And detecting means for automatically adjusting the resistance value of the resistor connected to the middle point of the third terminating resistor so that the potential difference detected by the detecting means becomes zero. The signal transmission system according to claim 10. 12. The signal transmission system according to claim 10, wherein a diode is connected to a midpoint of each of the first termination resistor, the second termination resistor, and the third termination resistor.

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